Reverse plaque formation by hog cholera virus of the GPE-strain inducing heterologous interference.

The general capacity of germfree mouse spleen cells to produce interferon in vitro in response to various stimuli was investigated. The interferon response of germfree mouse spleen cells in vitro, when compared with that of the conventionals, appears to be lower to some inducers. Interferon production in vitro stimulated by hemagglutinating virus of Japan (HVJ) or BHK-HVJ cells (BHK cells persistently infected with HVJ) was apparently suppressed in germfree mouse spleen cells as compared with the corresponding conventionals, whereas no difference of interferon production was observed between germfree and conventional mouse spleen cells in response to Newcastle disease virus, Escherichia coli endotoxin, poly(I:C), and phytohemagglutinin. Although monocontamination with HVJ had no enhancing effect on the interferon-producing ability of germfree mouse spleen cells in response to HVJ, conventionalization for 2 weeks greatly enhanced interferon-producing capacity.     

Iterferon induction in mice by BHK cells persistently infected with HVJ.

Intraperitoneal injection into mice of BHK-HVJ cells (BHK cells persistently infected with HVJ) induced considerable amounts of circulating interferon. Sonication of BHK-HVJ cells almost totally abolished their interferon inducing capacities. This result suggests that a certain native organized structure of virus infected cells might be essential for production of interferon in this system, as is suggested in the in vitro sytem.     

The effects of cytochalasin and colchicine on interferon production.

The present study was undertaken to investigate the mechanism of interferon production by mouse spleen cells co-cultivated with BHK-HVJ cells, i.e. baby hamster kidney cells persistently infected with the HVJ (or Sendai) strain of para-influenza I virus. Cytochalasin B appears to inhibit an early stage in the process and colchicine a relatively late stage. It is suggested that microfilaments and microtubules may play in important role at an initial stage of interferon production in this system.     

The mechanism of interferon induction in mouse spleen cells stimulated with HVJ.

This study showed that functional viral RNA and the penetration of virus into the cell are needed for interferon induction in L cells, while simple contact of the viral glycoprotein with the cell surface appears to be sufficient for interferon induction by the same HVJ in mouse spleen cells. Thirty minutes of uv irradiation resulted in complete loss of the interferon-inducing ability of HVJ in mouse L cells. In contrast to this result, HVJ irradiated for 2 hr could induce interferon in mouse spleen cells as efficiently as untreated HVJ. These findings showed that the actual inducer of interferon in mouse spleen cells was not viral nucleic acid, but some other viral component. When HVJ was treated with potassium periodate at 37° for 1 hr, infectivity for eggs and the hemolytic and neuraminidase activities of the virus were not detectable, but a considerable portion of its hemagglutinating activity was retained. The binding to erythrocytes of this inactivated HVJ, which showed no interferon-inducing ability in both L and mouse spleen cells, was restored in mouse spleen cells but not in L cells. The results indicated that hemolytic and neuraminidase activities are not essential for interferon induction in mouse spleen cells and that hemagglutinating activity might be closely related to interferon induction in the cells, although the presence of hemagglutinating activity alone is not sufficient for interferon induction in the cells. It seems that structural integrity of hemagglutinin on the erythrocyte surface may be important for interferon induction. HeLa cell-grown HVJ, which is characterized by its inability to penetrate into tissue culture cells, was found to stimulate interferon production in mouse spleen cells but not in L cells. This suggests that the process of virus penetration may be essential for induction of interferon in L cells. Interferon was produced in mouse spleen cells incubated with membranous particles with HVJ glycoproteins, but interferon activity could not be detected in the culture fluids of L cells. Aggregation of the glycoproteins by an antibody enhanced its interferon-inducing ability in mouse spleen cells. These results showed that the actual inducer of interferon in mouse spleen cells is not viral nucleic acid, but viral glycoproteins of HVJ, and that the size of its membranous structure is related to interferon inducibility. The mechanism of interferon induction by influenza virus in mouse spleen cells is similar to that of interferon induction by HVJ.     

Suppression of interferon production in mouse spleen cells by cytochalasin D.

Cytochalasin D is thought to impair microfilament function. The present study has investigated its effects on four different systems in which interferon is formed, namely (1) mouse fibroblasts induced with virus (2) mouse spleen cells induced with virus, or (3) with endotoxin or (4) by allogeneic stimulation. Cytochalasin D did not suppress formation of interferon by fibroblasts (L cells) or spleen cells stimulated with either HVJ or NDV. However it did suppress production of interferon by spleen cells in response to endotoxin or an allogeneic stimulation; here its action was apparently not on the secretion of interferon, but on some earlier event. It also suppressed the production of interferon by mouse spleen cells induced with HVJ if this had been u.v. irradiated for more than 15 min: this suggests that cytochalasin D sensitive structures do play some role in interferon production by mouse spleen cells when stimulated with HVJ, as well as when they are stimulated with endotoxin or an allogeneic stimulus.     

Host Defense Mechanisms Against Herpes Simplex Virus I. Control of Infection In Vitro by Sensitized Spleen Cells and Antibody

Sensitized mouse spleen cells decrease the spread of herpes simplex virus infection in cell culture lines derived from human and murine tissues. These washed, sensitized cells act alone and additively in combination with antibody to diminish the ability of single virus-infected cells to spread infection to contiguous cells. This control of infection is not species specific, unlike interferon, and appears to be distinct from the effect of antibody. Lymphotoxin was not detected in this lymphocyte-mediated response. This control of herpes simplex virus infection in vitro by sensitized lymphoid cells is immunologically specific; spleen cells from donor animals immunized with a heterotypic virus do not cause herpesvirus plaque size reduction. The ratio of spleen cells from immunized animals to target monolayer cells needed to produce this effect is > 4:1. Plaque size reduction of herpes simplex virus by spleen cells requires intact, immune, non-glass-adhering lymphoid cells.     

Component(s) of Sendai virus that can induce interferon in mouse spleen cells.

To identify the active component of Sendai virus that induces interferon in mouse spleen cells, infectious and noninfectious viruses, envelope particles derived from them, and isolated hemagglutinin-neuraminidase (HN) glycoproteins were examined for interferon induction. The interaction between membranous structures containing Sendai virus HN glycoprotein and the receptors on the cell surface was shown to be sufficient for interferon induction in mouse spleen cells, suggesting that the actual inducer of interferon in mouse spleen cells is the HN glycoprotein of Sendai virus. When mouse spleen cells were stimulated in vitro with Sendai virus grown in eggs or LLC-MK2 cells or with membranous structures containing glycoproteins obtained from these viruses, interferon could be detected in the culture fluid. Furthermore, isolated HN glycoprotein per se could induce interferon in the cells. A linear correlation was found between the titer of interferon induced and the hemagglutinating activity of the membranous structure containing the HN glycoprotein. It was concluded from these findings that HN glycoprotein was the active component of Sendai virus responsible for interferon induction in mouse spleen cells and that viral RNA and F glycoprotein were not required. The results also showed that the interaction between HN glycoprotein and receptors on the cell surface triggered production of type I interferon (IFN-alpha and IFN-beta). Although when Sendai virus was incubated at 56 degrees C for 5 min it lost its hemolytic and hemagglutinating activities, it induced a considerable amount of interferon in the culture fluid of mouse spleen cells. The interferon-inducing ability of heat-inactivated virus could be absorbed with mouse spleen cells but not with sheep erythrocytes or mouse erythrocytes, indicating that the inactivated virus retained ability to bind to mouse lymphoid cells.     

Interferon production in L cells persistently infected with hemagglutinating virus of Japan (HVJ).

The present study shows that when L cells persistently infected with hemagglutinating virus of Japan (HVJ) (L-HVJ cells) were incubated at 32°, the interferon-producing capacity of the cells was suppressed and was restored by the temperature shift-up to 38°. Synthesis of envelope protein antigen was not detected in the L-HVJ cells incubated at 38° which could produce interferon. Moreover, glutamine-starved L-HVJ cells did produce interferon even at 32°. The relationship between the suppressed state of interferon production and synthesis of viral envelope protein is discussed.     

Altered pattern of viral RNA synthesis in cells infected with standard and defective Sindbis virus

Serial passage of Sindbis virus on BHK cells results in the accumulation of defective interfering (DI) particles (Schlesinger et al., 1972). Cells infected with preparations of Sindbis passaged extensively on BHK cells (Sindbis H) produce reduced amounts of infectious virus and contain low levels of 42 S and 26 S RNA and 20 S RNase-resistant replicative form (RF). In Sindbis H-infected cells the major single-stranded RNA species sediments at 20 S and the RF at 12 S. The interfering component in Sindbis H is sensitive to ultraviolet light and indistinguishable from standard virions in haemagglutination inhibition tests.Sindbis M was prepared by passage of Sindbis H in suckling mouse brain. The presence of 42 S and 26 S single-stranded RNA and 20 S RNase-resistant RF in Sindbis M infected cells (up to passage 5) indicates that mouse brain-passaged Sindbis lacks demonstrable interfering components.     

Homologous interference induced by a temperature-sensitive mutant derived from an HVJ (Sendai virus) carrier culture.

Homologous interference between a temperature-sensitive small plaque mutant (HVJ-pB) derived from an HVJ (haemagglutinating virus of Japan - the Sendai strain of parainfluenza I virus) carrier culture of BHK cells and the original wild-type virus (HVJ-W) has been investigated. Prior infection of LLCMK2, HeLa, BHK or mouse L cells with HVJ-pB, both at permissive and non-permissive temperatures, for 24 h resulted in a reduced yield of superinfecting HVJ-W, reflecting a smaller number of cells capable of producing the superinfecting virus. However, HVJ-pB did not interfere with the replication of vesicular stomatitis virus, Sindbis virus or Newcastle disease virus. Interference in this system seems to be due to inhibition of the attachment of superinfecting HVJ-W as a result of intracellular mechanisms operating at a late stage in the replication of the interfering virus. There is also blocking or destruction of cellular receptors by extra-cellular particles of the interfering virus. Protein synthesis coded for by the complete virus genome is required to establish and maintain the interference, and treatment with actinomycin D has no effect on the interference phenomenon.     

Secondary cytotoxic cell response to lymphocytic choriomeningitis virus. I. Kinetics of induction in vitro and yields of effector cells.

Secondary (memory) cell-mediated cytotoxic responses in lymphoid cells from CBA/H mice pre-primed with lymphocytic choriomeningitis virus (LCM) 5-7 weeks previously were induced by culturing these cells in vitro with syngeneic, infected peritoneal cells at 37 degrees for periods of up to 5 days. Cytotoxic effectors were assayed against LCM infected, H-2 compatible target cells in a 51Cr release assay. Response was greater with a higher ratio (1:10) of infected peritoneal cells:pre-primed cells than with lower ratios (e.g. 1:250). Separating responders from infected cells by a 450 mmum nucleopore membrane (coarse enough to allow passage of virus particles) still permitted induction of a secondary response whilst interposition of a 50 mmum nucleopore membrane (which apparently prevented transit of virus particles) virtually abolished the secondary response. Removal of phagocytic cells from responders prior to setting up memory cultures greatly reduced responders' capacity to be induced. Fixed, infected stimulators still induced strong secondary responses. Secondary response was maximal with spleen cells, peripheral blood lymphocytes, or pooled iliac and lumbar lymph node cells. Thymocytes responded less well, whilst mesenteric lymphoid cells and peritoneal cells gave minimal responses. Effector cells from memory cultures killed targets with single-hit kinetics and a rectilinear log effectors: log targets lysed relation held. Memory spleen cells developed increasing cytolytic activity from 2 to 5 days in culture. Memory-generated effectors were markedly potent by day 5, e.g. giving 70 per cent specific release at a killer:target ratio of 0-8:1. Peak DNA synthesis occurred on day 4. We conclude that memory effectors as a population differ in kinetics and potency from effectors obtained by primary viral challenge in the mouse.     

Cell-mediated immune responses in vitro. V. A comparative study of in vitro immunogenicity of splenic lymphocytes, neoplastic lymphoid cells and fibroblats

This study compares the effectiveness of mouse lymphocytes, neoplastic lymphoid cells or fibroblasts in stimulating allogeneic cells to embark on an in vitro cytotoxic response, as measured by a ⁵¹Cr release assay. In addition, during ontogeny of mouse spleen cells, their capacity to stimulate in the mixed lymphocyte culture (MLR) was compared to their capacity to stimulate cytotoxic allograft responses. During ontogeny, there was amarked increase in the capacity of mouse spleen cells to stimulate mitotic responses in the MLR. In contrast, the magnitude of cytotoxic allograft responses induced by neonatal mouse spleen cells in the cytotoxic allograft system was comparable in magnitude to that induced by spleen cells of adult mice. The immunogenicity of subpopulations of mouse spleen cells was investigated. Mouse lymphoid cell populations, enriched for B or T lymphocytes or hemopoietic stem cells were equally immunogenic in vitro, as were myeloma or thymoma lymphoid cells. In contrast, mouse fibroblasts were found to elicit poor cytotoxic allograft responses. In fact, lymphoid cells were about 20–40-fold more immunogenic than fibroblasts.     

Characterization of the polypeptides synthesized in cells infected with a temperature-sensitive mutant derived from an HVJ (Sendai virus) carrier culture

Summary The intracellular synthesis of virus-specific polypeptides in cells infected with the wild-type virus of HVJ (HVJ-W) (haemagglutinating virus of Japan—the Sendai strain of parainfluenza 1 virus) and with a temperature-sensitive(ts) mutant (HVJ-pB) derived from an HVJ carrier culture has been analysed by polyacrylamide gel electrophoresis. At the permissive temperature (32° C), all of the known virus structural polypeptides were identified in cells infected with each strain of virus and in addition to the non-structural polypeptides B and C, another polypeptide at the region with a molecular weight of 26,000 to 27,000 (26 to 27K) could be detected in infected cells. At the non-permissive temperature (38° C), the synthesis of the polypeptide M was markedly restrained in cells infected with HVJ-pB, while other major virus polypeptides were present in approximately comparable amounts to cells infected with the wild-type virus. A non-structural polypeptide with a molecular weight of 105K was dominant ints mutant infected cells at higher temperatures and disappeared after temperature-shift from 38° to 32° C. The production of the non-structural polypeptides B and 27K was also temperature-sensitive. The molecular weights of the polypeptides B, M and 27K in HVJ-pB infected cells were larger than those of the corresponding polypeptides in HVJ-W infected cells. The synthesis of the M protein in HVJ-pB infected cells started just after lowering the incubation temperature and the newly made M protein was successfully incorporated into virus particles.With 4 Figures     

Growth of malignant rabbit fibroma virus in lymphoid cells

To understand better the immunosuppressive capacity of malignant rabbit fibroma virus (MV), we characterized MV growth in lymphoid cells. Replication of MV occurs in unstimulated normal spleen cells in vitro and is enhanced by adding T- or B-lymphocyte mitogens. In splenic T-lymphocyte preparations, comparable results are found: virus growth in the absence of mitogen, augmented by adding Con A. Unlike mature T cells, thymic lymphocytes support MV replication only when mitogen is added. When spleen cells from rabbits infected with MV in vivo are removed and cultured without mitogen, MV growth is again observed, with virus titer increasing about 10-fold per day of culture. In spleen cell populations from MV tumor-bearing rabbits, MV grows best in T lymphocytes, moderately in B lymphocytes, and least efficiently in adherent cells. When spleen cells are examined immediately following sacrifice, MV antigens are expressed solely on T lymphocytes from rabbits infected in vivo with MV 7 days previously. However, following overnight incubation in vitro a population of non-T lymphocytes displays cell membrane virus antigens. MV adapts itself somewhat to growth in lymphocytes, showing significantly greater growth in lymphocytes following passage in lymphocytes than is observed for non-lymphocyte-propagated virus. MV-infected lymphocytes also elaborate a factor that enhances MV growth in lymphocytes. Thus, MV replicates preferentially in mature T lymphocytes but will grow well in B cells as well. In vivo infection produces relatively small amounts of recoverable virus. However, when these lymphocytes are cultured in vitro virus replicates very well without added mitogens. These growth patterns may help to understand MV-induced immunologic dysfunction.     

Assembly of viral structural proteins in cells infected with a temperature-sensitive mutant derived from an HVJ (Sendai virus) carrier culture

Summary The processing of virus polypeptides synthesized in cells infected with HVJ (haemagglutinating virus of Japan—the Sendai strain of parainfluenza 1 virus) was studied. Maturation of a temperature-sensitive(ts) mutant (HVJ-pB) derived from an HVJ carrier culture was inhibited at 38° C incubation. A considerable amount of viral components were made at the restrictive temperature. They were, with the exception of the polypeptide HN, well preserved without a great loss of their function and successfully incorporated into virus particles released after lowering the incubation temperature. The membrane (M) protein seems to be essential for virus morphogenesis.With 1 Figure     

Natural interferon-producing cells in mice.

When mouse lymphoid cells derived from untreated C57BL/6 mice were cocultivated in liquid cultures with L-cell monolayers for 3 h, overlaid with soft agar, and then further incubated for 12 h, protected foci of L cells against vesicular stomatitis virus infection were formed. Many strains of mice have been found to have the protected focus-forming cells on the L-cell monolayers. The formation of the protected foci was completely suppressed by addition of cycloheximide into soft agar. When anti-interferon (type I) antiserum was added to soft agar, there was a decrease in focus counts of about 80%. These experimental results indicated that the formation of protected foci by untreated mouse lymphoid cells was mediated for the most part by type I interferon that was produced without addition of special inducer. We have designated these focus-forming cells as natural interferon-producing cells (NIPC). NIPC belong to the glass-adherent fraction, and Thy-1 antigen, immunoglobulin, and Ia antigen could not be detected on the surface of the NIPC. NIPC were detected in congenitally athymic nude mice. These findings suggest that NIPC belong to the Ia-negative macrophages. Mouse lymphoid cells obtained from germfree mice could form the protected foci on L-cell monolayers and could produce interferon without the addition of a special inducer. NIPC are considered to be a cellular background for spontaneous interferon production.     

Characterization of altered BHK cells resistant to HVJ (Sendai virus) infection

An altered baby hamster kidney cell culture which resists the c.p.e. of HVJ (haemagglutinating virus of Japan - the Sendai strain of parainfluenza I virus) has been obtained and characterized. These cells, designated BHK-R, were originally obtained by prolonged cultivation of cells surviving HVJ infection; they have been subcultured in the presence of HVJ. No infectious virus was recovered from BHK-R cells and no evidence for the presence of HVJ antigens in the cells was demonstrated by immunofluorescent staining. When BHK-R cells were inoculated with HVJ the growth of challenge virus was suppressed and no obvious cytopathic changes were detected, while these cells normally supported the replication of mumps, influenza, Newcastle disease, vesicular stomatitis or Sindbis viruses. BHK-R cells became susceptible to HVJ infection after serial subculture in growth medium free of HVJ. It was suggested that sialic acid residues present in the surface of BHK-R cell membranes and responsible for adsorption of HVJ were split off by the action of neuraminidase of virus particles, resulting in inhibition of the attachment of challenge virus of HVJ.     

Persistent infection with mouse hepatitis virus 3 in mouse lymphoid cell lines

The sensitivity of mice to mouse hepatitis virus 3 (MHV3) varies according to strain, age, and immune status of the animals. In semisusceptible strains, mice surviving the acute phase of infection develop a chronic disease characterized by the occurrence of paralysis, virus persistence, and immunodeficiency. Persistent MHV3 infections established in vitro in YAC and RDM -4 mouse lymphoid cell lines were characterized by virus production, presence of cytoplasmic viral antigens, and cell lysis. The occurrence of cell "crisis" in YAC cells was manifested by a sharp increase in cell lysis and in the number of fluorescent cells and, concomitantly, by a marked decrease in virus titers. A relationship was observed among the percentage of fluorescent cells, cell lysis, and virus yield and was modulated by renewal of culture media, change in temperature, or inhibition of cellular RNA synthesis. Cell cloning and antibody treatment experiments indicated that viral transmission was performed by viral infection of newly permissive cells produced by the division of uninfected cells in the culture and not by transmission of viral information by infected dividing cells. The biological and biochemical properties of MHV3 variants derived from persistently infected YAC lymphoid cells were characterized. Thermosensitivity and thermolability of cloned viruses originating from persistently infected YAC cells, as well as parent virus suspensions, were studied. A similar heterogeneity was observed when YAC-derived cloned substrains (YAC-MHV3) were compared with parent-derived cloned viruses, indicating that no selection of temperature-sensitive mutants was induced in persistently infected YAC cells. However, the capacity of MHV3 to induce a lethal acute disease when injected into susceptible mice was lost very rapidly. The absence of pathogenicity was related to the induction of a subclinical infection which elicited defense mechanisms. These data suggest, therefore, that MHV3 replication in lymphoid cell lines leads to induction or selection of variants which maintain pathogenicity in vitro but display reduced pathogenic effects in vivo.